experiment objective

abstract

Ferrofluids are carrier liquids in which magnetic nanoparticles are suspended. The behaviour of ferrofluids in microgravity is largely unexplored because experiments in microgravity are expensive and the access to associated facilities is limited. It would be beneficial for both fundamental research and future applications of ferrofluids in Space to obtain a computational fluid dynamics model of ferrofluids in microgravity conditions. However, experimental data to validate such models is hardly available. Therefore, this experiment aims to quantify the free surface movement of ferrofluids in microgravity under the influence of a magnetic field and certain external oscillation/actuation. The second objective is to compare this experimental data with predictions of a CFD model in order to validate its dynamics.

To accomplish these objectives, an experiment set-up was designed that imposes a well- defined magnetic field on a solution of water-based ferrofluids inside two cylindrical Plexiglass containers. The novelty of the design is reflected in two aspects. First of all, the dynamics of a ferrofluid in microgravity were never studied under the influence of both a constant magnetic field and a percussion mechanism. Secondly, the design is such that it avoids obscuring the video images because of the ferrofluid wetting of the container surfaces, and enables reliable postprocessing, in contrast with preceding experiments.

The experiment will be launched 5 times in the ZARM Drop Tower in Bremen. In order to obtain a wide range of testing conditions. During the post-processing of the video data, a 3D representation of the ferrofluid free-surface surface will be constructed and relevant dynamical parameters will be extracted. We plan to publish our results (experimental data and related conclusions drawn) to the academic society via papers and conferences, but are also actively involving the general public through public outreach activities.